Methods and systems for projecting augmented reality content

ABSTRACT

An augmented reality presentation system directs a sensor included within an augmented reality projection device to capture an image of a portion of a real-world environment included within a field of view of the sensor. As the sensor captures the image, the system determines that a target object located within the real-world environment is included within the field of view of the sensor, and identifies augmented reality content associated with the target object. As the sensor continues capturing the image, the system directs a projector included within the augmented reality projection device to project the augmented reality content onto a physical surface within the real-world environment and associated with the target object. The physical surface is physically detached from the augmented reality projection device and is included within the field of view of the sensor while the augmented reality content is projected onto the physical surface.

BACKGROUND INFORMATION

Users of augmented reality player devices (e.g., augmented realityglasses, mobile devices running augmented reality applications, etc.)may experience an augmented version of the real-world environment aroundthem. For example, an augmented reality player device may presentaugmented reality content to a user on a display associated with theaugmented reality player device (e.g., on a heads-up display projectedonto partially-transparent augmented reality glasses worn by the user,on a screen of a mobile device held by the user, etc.). For instance,the augmented reality content may be overlaid, within the display, onthe user's view of the real-world environment around him or her. In thisway, the user may not only experience (e.g., see, hear, and/or otherwiseperceive or interact with) the real-world environment, but may furtherexperience various augmentations to the real-world environment such asobjects, characters, information, and the like that are not actuallypresent in the real-world environment.

While such augmented reality experiences may be beneficial to a userpossessing a personal augmented reality player device configured topresent the overlaid augmented reality content on a device display, suchaugmentations are not visible in the real-world environment without thedevice display. As such, the user may only experience the augmentedreality content by way of display equipment (e.g., glasses, displayscreens, etc.) associated with the personal augmented reality device.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings illustrate various embodiments and are a partof the specification. The illustrated embodiments are merely examplesand do not limit the scope of the disclosure. Throughout the drawings,identical or similar reference numbers designate identical or similarelements.

FIG. 1 illustrates an exemplary augmented reality presentation systemassociated with an exemplary augmented reality projection device forprojecting augmented reality content into a real-world environmentaccording to principles described herein.

FIG. 2 illustrates an exemplary integrated implementation of theaugmented reality presentation system and the augmented realityprojection device of FIG. 1 according to principles described herein.

FIG. 3 illustrates exemplary operations that may be performed by anaugmented reality presentation system to project augmented realitycontent into a real-world environment according to principles describedherein.

FIG. 4A illustrates an exemplary physical target object physicallylocated within an exemplary real-world environment according toprinciples described herein.

FIG. 4B illustrates exemplary virtual target objects virtually locatedwithin an exemplary real-world environment according to principlesdescribed herein.

FIG. 5 illustrates an exemplary image capture operation being performedby the integrated implementation of the augmented reality presentationsystem and the augmented reality projection device of FIG. 2 accordingto principles described herein.

FIG. 6 illustrates an exemplary target object recognition operationbeing performed by the integrated implementation of the augmentedreality presentation system and the augmented reality projection deviceof FIG. 2 according to principles described herein.

FIG. 7 illustrates an exemplary library of predefined target objectprofiles according to principles described herein.

FIG. 8 illustrates an exemplary content projection operation beingperformed by the integrated implementation of the augmented realitypresentation system and the augmented reality projection device of FIG.2 according to principles described herein.

FIG. 9A illustrates an exemplary projection stabilization operationbeing performed by the integrated implementation of the augmentedreality presentation system and the augmented reality projection deviceof FIG. 2 according to principles described herein.

FIG. 9B illustrates another exemplary projection stabilization operationbeing performed by the integrated implementation of the augmentedreality presentation system and the augmented reality projection deviceof FIG. 2 according to principles described herein.

FIG. 10 illustrates an exemplary method for projecting augmented realitycontent into a real-world environment according to principles describedherein.

FIG. 11 illustrates another exemplary method for projecting augmentedreality content into a real-world environment according to principlesdescribed herein.

FIG. 12 illustrates an exemplary computing device according toprinciples described herein.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Methods and systems for projecting augmented reality content into areal-world environment are described herein. For example, in certainimplementations, an augmented reality presentation system may direct asensor included within an augmented reality projection device to capturean image of a portion of a real-world environment. Specifically, theportion of the real-world environment captured by the sensor may be aportion that is included within a field of view of the sensor. Invarious examples described herein, the sensor included within theaugmented reality projection device may be implemented by a cameraconfigured to capture an image implemented by a video feed. As such, thefield of view of the camera may refer to a portion of the real-worldenvironment that is captured by the camera (e.g., based on lenses withinthe camera, the resolution of the camera, etc.). While the followingexample, and various other examples illustrated and described herein mayrefer to cameras that capture video feeds, however, it will beunderstood that other types of sensors configured to capture other typesof images using other types of fields of view may also be used inaccordance with principles described herein. For instance, a sensor maybe implemented as a depth sensor (e.g., a LIDAR scanner, etc.) thatdetects and tracks images such as point clouds representative of depthpoints of objects being scanned, as a scanner that uses one or morelasers to detect information encoded in images (e.g., visual patterns)such as barcodes or QR codes, and/or as any other type of camera,scanner, or other sensor as may serve to capture any type of image in aparticular implementation. In any of these examples, a field of view ofthe sensors may refer to a portion of the real-world environment that iswithin the scannable range of the depth sensor, scanner, or othersuitable sensor.

As a camera (i.e., the sensor) captures a video feed (i.e., the image),the augmented reality presentation system may determine that a targetobject (e.g., a target object located within the real-world environment)is included within the field of view of the camera, and may identifyaugmented reality content associated with the target object. As thecamera continues capturing the video feed, the augmented realitypresentation system may direct a projector included within the augmentedreality projection device to project the identified augmented realitycontent onto a physical surface within the real-world environment. Forexample, the physical surface may be a surface associated with thetarget object (e.g., a wall, a floor, a door, an object surface, etc.)and physically detached from the augmented reality projection device. Insome examples, the physical surface may be included within the field ofview of the camera while the augmented reality content is projected ontothe physical surface.

As will be described in more detail below, in certain examples, anaugmented reality projection device may be separate from, butcommunicatively coupled with, an augmented reality presentation systemthat performs the operations described above with respect to components(e.g., a camera component, a projector component, etc.) of the augmentedreality projection device. For instance, an augmented realitypresentation system may be implemented by a computing systemcommunicatively coupled to an augmented reality projection device by wayof one or more networks (e.g., including wireless networks). In otherexamples, an augmented reality projection device may include anaugmented reality presentation system integrated within a singleenclosure of the augmented reality projection device that also containsthe camera, the projector, and other components of the augmented realityprojection device.

Accordingly, in some exemplary implementations, a camera included withinan augmented reality projection device may capture a video feed of aportion of a real-world environment, where the portion of the real-worldenvironment is a portion included within a field of view of the camera.The augmented reality projection device may determine, as the cameracaptures the video feed, that a target object (e.g., a target objectthat is located within the real-world environment) is included withinthe field of view of the camera. The augmented reality projection devicemay identify augmented reality content associated with the targetobject. Then, as the camera continues capturing the video feed, aprojector (e.g., a projector statically mounted alongside the camerawithin the augmented reality projection device) may project theaugmented reality content onto a physical surface within the real-worldenvironment. As with the implementations described above, the physicalsurface onto which the augmented reality content is projected may beassociated with the target object (e.g., part of the target object,adjacent to the target object, etc.) and may be physically detached(i.e., separate) from the augmented reality projection device. Moreover,the physical surface onto which the augmented reality content isprojected may be included within the field of view of the camera whilethe augmented reality content is projected onto the physical surface.

In some examples, the augmented reality projection device (e.g., basedon direction from an integrated or a separate augmented realitypresentation system) may dynamically stabilize a projection of theaugmented reality content at a particular portion of the physicalsurface in response to a change to at least one of a position and anorientation of the augmented reality projection device with respect tothe particular portion of the physical surface. Specifically, theaugmented reality projection device may dynamically stabilize theprojection in real time as the position and/or orientation of theaugmented reality projection device (e.g., including the projectorwithin the augmented reality projection device) is moved about withrespect to the physical surface. For example, the augmented realityprojection device may be implemented as a handheld device that a userholds and points at different portions of the real-world environment ina similar way as one might hold and point a flashlight in a darkenedroom. However, whereas an ordinary flashlight uses light to revealobscured details of real-world objects under the beam of the flashlight,the augmented reality projection device may use a camera and a projectorto “reveal” (i.e., project) augmentations to the real-world environmentassociated with particular real-world objects and/or locations.

Just as most real-world objects would remain static as a flashlight beammoves across them (or at least move independently from the flashlightbeam), it may be desirable for augmented reality content projected bythe augmented reality projection device (e.g., augmented reality contentassociated with target objects that have been recognized and identified)to likewise be dynamically stabilized so as to remain staticallyanchored in one place in spite of how a user may move the augmentedreality projection device. By being dynamically stabilized in this way,even as the projector is pointed in different directions and/or movedabout within the real-world environment, it may seem to the user thatthe augmentations are similar to real-world objects within thereal-world environment, except that the augmentations may only beexperienced (e.g., seen, heard, or otherwise perceived) using theflashlight-like functionality of the augmented reality projectiondevice.

Accordingly, “stabilized” augmented reality content may refer toaugmented reality content that is projected into a real-worldenvironment so as to have a particular location, size, orientation,etc., that is independent of the location, field of view, orientation,etc. of the projector projecting the augmented reality content.Accordingly, stabilized augmented reality content may be projected ontoa physical projection surface by a projector that is detached from theprojection surface and is free to move in any way with respect to theprojection surface. However, the stabilized augmented reality contentmay appear to be statically located, sized, oriented, etc., with respectto the projection surface, rather than with respect to the projector, aswould be the case with an ordinary static projection of content.

In some examples, the stabilization of augmented reality content may beperformed dynamically (e.g., continuously, based on up-to-dateinformation) and in real time. As used herein, operations may beperformed in “real time” when performed immediately and without unduedelay. As such, while dynamic stabilization may not occurinstantaneously (i.e., augmented reality content may not remainperfectly static and/or stabilized as an augmented reality projectiondevice is moved), moment-by-moment stabilization corrections may beperformed as the projector and/or the physical projection surface movewith respect to one another, and augmented reality content may bereadjusted to a desirable size, location, orientation, etc., as quicklyas possible (e.g., within milliseconds or seconds of the detectedchanges).

Method and systems described herein for projecting augmented realitycontent into a real-world environment may provide various benefits,particularly when the augmented reality content projected is stabilized,as described above. For example, while users conventionally have had toview a special display associated with an augmented reality playerdevice in order to benefit from augmentations to the real-worldenvironment, methods and systems described herein allow users toexperience and share augmented reality without a need for the specialdisplays. As a result, users of augmented reality projection devices mayavoid discomfort, inconvenience, stigma, cost, and so forth that may beassociated with immersive augmented reality displays such as augmentedreality headsets, augmented reality glasses, and the like. At the sametime, the users may still be immersed in an augmented reality worldwhere augmented reality content is displayed in association withreal-world objects that the content corresponds to, rather than havingto view the augmented reality world in a less immersive way such as byexperiencing the world through a screen of an augmented reality mediaplayer (e.g., a smartphone device, a tablet device, etc.) held at arm'slength.

Additionally, because augmented reality content is actually projectedonto physical surfaces within the real-world environment, the augmentedreality content may benefit (e.g., inform, entertain, be perceived by,etc.) not only the user of the augmented reality projection device, butalso other people in the real-world environment with the user. Forinstance, in an example where augmented reality content is associatedwith exhibits at a museum and is configured to reveal additionalinformation (e.g., written text, videos, etc.) about each exhibit,conventional augmented reality technology may require each museum patronto have his or her own augmented reality player device to experience theaugmented reality content. In contrast, a single augmented realityprojection device described herein, if used by just one person in agroup of people touring the museum together, would allow everyone in thegroup to experience the augmented reality content simultaneously.

Various embodiments will now be described in more detail with referenceto the figures. The disclosed systems and methods may provide one ormore of the benefits mentioned above and/or various additional and/oralternative benefits that will be made apparent herein.

FIG. 1 illustrates an exemplary augmented reality presentation systemassociated with an exemplary augmented reality projection device forprojecting augmented reality content into a real-world environment.Specifically, FIG. 1 shows an augmented reality presentation system 100(“system 100”) that includes, without limitation, a capture facility102, a data processing facility 104, an augmentation facility 106, and astorage facility 108 selectively and communicatively coupled to oneanother. FIG. 1 further shows an augmented reality projection device 110(“device 110”) associated with system 100 and that includes, withoutlimitation, a sensor 112 and a projector 114.

It will be recognized that although facilities 102 through 108 are shownto be separate facilities in FIG. 1, facilities 102 through 108 may becombined into fewer facilities, such as into a single facility, ordivided into more facilities as may serve a particular implementation.Each of facilities 102 through 108 may be distributed between multipledevices and/or multiple locations as may serve a particularimplementation. Additionally, one or more of facilities 102 through 108may be omitted from system 100 in certain implementations, whileadditional facilities may be included within system 100 in the same orother implementations.

Additionally, it will be understood that although system 100 and device110 are depicted as separate entities associated with one another by wayof an arrow, the association between system 100 and device 110 mayrepresent any relationship including a complete integration with oneanother. For instance, in some examples, system 100 may be separate fromand communicatively coupled with device 110 (i.e., such that the arrowrepresents any suitable communication interface between system 100 anddevice 110 such as a network-based communication interface). In otherexamples, system 100 may be integrated with (e.g., included within)device 110 and/or may include or integrate device 110 (i.e., such thatthe arrow represents an integration of system 100 and device 110 into asingle unit). In the same or other examples, facilities 102 through 108of system 100 may be distributed across multiple systems and/or devicessuch as by being partially implemented in one or more computing devicesimplementing system 100 and partially implemented within sensor 112,projector 114, and/or other components of device 110. Each of thecomponents of system 100 and device 110 will now be described in moredetail.

Capture facility 102 may include any hardware and/or software (e.g.,image sensors or scanners associated with or included within sensor 112,network interfaces, computing devices, software running on orimplementing such devices or interfaces, etc.) that may be configured toperform image capture operations for projecting augmented realitycontent into a real-world environment as described herein. For example,capture facility 102 may direct sensor 112 within device 110 to capturean image (e.g., a video feed, a still image, a barcode, etc.) of aportion of a real-world environment (e.g., a portion of the real-worldenvironment that is included within a field of view of sensor 112). Ifdevice 110 is separate from system 100, capture facility 102 may performthe directing of sensor 112 to capture the image by transmittinginstructions to this effect over a communication interface (e.g., over anetwork or the like) to device 110 to be performed by sensor 112. If,however, device 110 is integrated with system 100, capture facility 102may be integrated within sensor 112 as a hardware or software controllerfor one or more image sensors included within sensor 112. In this typeof implementation, capture facility 102 may thus direct sensor 112 tocapture the image by direct control of sensor 112 as will be illustratedand described below.

Data processing facility 104 may include one or more physical computingdevices (e.g., the same hardware and/or software components includedwithin capture facility 102 and/or components separate from those ofcapture facility 102) that perform various data processing operationsfor projecting augmented reality content into the real-worldenvironment. For example, data processing facility 104 may perform anoperation to determine (e.g., based on the image as the camera capturesthe image) that a target object located within the real-worldenvironment is included within the field of view of sensor 112. Forinstance, such a determination may be made based on object recognitionof a physical target object visible within images of the image, based ona detected location and orientation of sensor 112 (e.g., to determinethat a non-visible virtual target object is within the field of view ofsensor 112), and/or in any other manner and based on any other data asmay serve a particular implementation. As another example of a dataprocessing operation, data processing facility 104 may identifyaugmented reality content associated with the target object. Forexample, augmented reality content may be identified to be associatedwith a detected target object in a target object profile in a library ofpredetermined target object profiles, identified by searching forrelevant augmented reality content by way of a database or Internetsearch or the like, or otherwise identified (e.g., found, accessed,downloaded, generated, discovered, etc.) in any manner as may serve aparticular implementation.

Like facilities 102 and 104, augmentation facility 106 may include oneor more physical computing devices (e.g., the same hardware and/orsoftware components included within facilities 102 and/or 104 orcomponents separate from those of facilities 102 and/or 104) thatperform various augmentation operations for projecting the augmentedreality content identified by data processing facility 104 into thereal-world environment. For example, augmentation facility 106 mayperform an operation to direct (e.g., based on the image as sensor 112continues capturing the image) projector 114 within device 110 toproject the identified augmented reality content onto a physical surfacewithin the real-world environment and associated with the target object.The physical surface may be physically detached from device 110 and/orsystem 100 and may be included within the field of view of sensor 112while the identified augmented reality content is projected onto thephysical surface. If device 110 is separate from system 100,augmentation facility 106 may perform the directing of projector 114 toproject the augmented reality content by transmitting instructions tothis effect over a communication interface (e.g., over a network or thelike) to device 110 to be performed by projector 114. If, however,device 110 is integrated with system 100, augmentation facility 106 maybe integrated within projector 114 as a hardware or software controllerfor one or more projection components included within projector 114. Inthis type of implementation, augmentation facility 106 may thus directprojector 114 to project the augmented reality content onto the physicalsurface by direct control of projector 114, as will be illustrated anddescribed below.

Storage facility 108 may include image data (e.g., image data (e.g.,video data), augmented reality content data, etc.) and/or any other datareceived, generated, managed, maintained, used, and/or transmitted byfacilities 102 through 106. In some examples, storage facility 108 mayinclude data used to facilitate operations of facilities 102 through 106such as buffering spaces for storing image data, program code,variables, intermediate content used in the preparation and/orgeneration of augmented reality content, and/or any other signals ordata used to implement methods and systems described herein as may servea particular implementation.

Within device 110, sensor 112 may include one or more image sensors(e.g., CMOS image sensors, CCD image sensors, etc.), image scanners(e.g., lasers for scanning barcodes or the like, etc.), as well ashardware (e.g., logic, microcontrollers, etc.) and/or software forcontrolling the image sensors and/or scanners to capture, store, andtransmit images such as an ongoing video image to be provided by sensor112 in an image. Exemplary image sensors and control modulesimplementing sensor 112 will be described below for an example in whichsensor 112 is implemented as a camera configured to capture a videofeed. However, as described above, it will be understood that in otherexamples sensor 112 may be implemented as an image scanner, a cameraconfigured to capture only still frame photos, or any other type ofsensor as may serve a particular implementation.

Projector 114 may include one or more projection components (e.g., LCDlight gates, digital micromirror devices, light sources such as arraysof LEDs, etc.), as well as hardware and/or software for controlling theprojection components to receive, prepare, and project images ofaugmented reality content into a real-world environment (e.g., onto aphysical surface within the real-world environment). Exemplary projectorcomponents and control modules implementing projector 114 will bedescribed below.

FIG. 2 illustrates an exemplary integrated implementation of system 100and device 110. More particularly, an augmented reality projectiondevice 200 (“device 200”) shown in FIG. 2 may implement both system 100and device 110 as they were described above. To this end, as shown,device 200 includes a plurality of components incorporated within anenclosure 202 that includes one or more buttons 204 or other such userinterface elements external to enclosure 202 to allow a user of device200 to use and control the device as the user may desire in accordancewith functionality described herein. In some examples, enclosure 202,within which device 200 is implemented, may be a personal device (e.g.,a device that is relatively small, battery-powered, self-contained,etc., and that may be carried by hand, worn on the person of the usersuch as strapped to the head or the arm, etc.). As such, device 200 maybe conveniently operated by an individual user in an analogous manner asthe user might use a flashlight, headlamp, or the like. While device 200is depicted and will be described as an integrated implementation ofsystem 100 and device 110, it will be understood that a non-integratedimplementation of device 110 may include the same or similar componentsas illustrated within device 200, but may further include components forcommunicating with a separate system 100 that may exchange data with,and provide direction to, the implementation of the non-integratedaugmented reality projection device.

As shown, various components may be incorporated within enclosure 202 ofdevice 200. For example, an image control module 206 may becommunicatively coupled with an image sensor 208, which may use a lens210 to capture light representative of an image 212 of a real-worldenvironment in which device 200 is located. Collectively, image controlmodule 206, image sensor 208, and lens 210 may, along with othersuitable components, implement a camera (e.g., a camera implementingsensor 112, described above). As shown, in some examples, both thecamera and the projector may be included together (e.g., staticallymounted alongside one another) within a single enclosure such asenclosure 202. In other examples, however, it will be understood that adistributed configuration, in which all of the components of device 200are not enclosed in an integrated enclosure, may be employed. Forinstance, the camera of device 200 may be implemented as a cameraincluded in a mobile device (e.g., a smart phone) while the projector ofdevice 200 may be implemented as a separate device in an enclosureseparate from the mobile device.

Alongside these components implementing the camera, several componentsthat collectively implement a projector such as projector 114, describedabove, may be mounted (e.g., statically mounted) within enclosure 202.Specifically, as shown, the projector may be implemented by an imageprojection control module 214 communicatively coupled with a projectorcomponent 216, which may use a lens 218 to project light of a projection220 onto a physical surface within the real-world environment in whichdevice 200 is located.

Image control module 206 may be configured to direct image sensor 208and lens 210 to capture the light representative of image 212. To thisend, control module 206 may be associated with logic (e.g., one or moremicrocontrollers or other processors), memory, non-transitory storage,communication interfaces, and so forth to control image sensor 208 andlens 210, as well as to perform certain data processing operations withrespect to image data (e.g., a video feed) captured by image sensor 208.For example, image control module 206 may at least partially implementdata processing facility 104 described above and, as such, may determinethat a target object is included within a field of view of the camera(e.g., is represented within the image received from image sensor 208),may identify augmented reality content associated with the targetobject, and so forth.

Image sensor 208 may capture the video feed by sensing (e.g., detecting,capturing, etc.), under direction of image control module 206, lightcoming in through lens 210. For example, image sensor 208 may beimplemented by a CMOS image sensor, a CCD image sensor, or another imagesensor employing another suitable digital or analog image sensingtechnology.

For reasons that will be made apparent, a dynamic range of device 200may be influenced or determined by various characteristics associatedwith a field of view of a camera included within device 200. Forexample, characteristics such as a resolution of image sensor 208, amagnification power of lens 210, and/or other optical or electricalcharacteristics of the camera may serve as determining factors for thedynamic range of device 200 (e.g., how well device 200 can function atdifferent locations, orientations, etc., with respect to target objectsand/or projection surfaces in the real-world environment).

As a result, it may be desirable to employ different image sensors 208and/or different lenses 210 to implement different characteristics(e.g., different resolutions, different magnification powers, differentimage sensing technologies, etc.) at different times. For example, whendevice 200 is detected to be relatively close to a target object in thereal-world environment (e.g., such that the target object fills up arelatively large amount of the available resolution of one image sensor208), it may be desirable to use a different lens 210 (e.g., a widerangle lens) and/or a different image sensor 208 than when device 200 isdetected to be relatively remote to the target object (e.g., such thatthe target object fills up a relatively small amount of the availableresolution of the image sensor 208). To this end, as certainimplementations of image control module 206 direct image sensor 208 tocapture light of image 212, the image capture may include selecting asensor parameter associated with the field of view of the camera. Forexample, the sensor parameter may designate a particular image sensor208 from a plurality of different image sensors (e.g., each havingdifferent characteristics such as different resolutions) included withinthe camera. As another example, the sensor parameter may designate aparticular lens 210 from a plurality of different lenses (e.g., eachproviding a different magnification power such as a wide-anglemagnification power or a narrow-angle magnification power for the fieldof view) included within the camera.

Additionally, or as an alternative to including pluralities of differentimage sensors and/or different lenses, the configuration of image sensor208 with respect to lens 210 (e.g., or an adjustable set of lensescollectively implementing lens 210) may also be altered to achieve someof the differences in characteristics described above. For example, thecamera may achieve different characteristics by mechanically and/orelectrically reconfiguring (e.g., sliding, repositioning, etc.) imagesensor 208, lens 210, or components associated therewith (e.g., mirrors,fixtures having different lenses that may be electrically ormechanically activated, etc.). Thus, another exemplary sensor parameterthat may be selected by device 200 (e.g., by image control module 206)may designate a particular optical configuration from a plurality ofdifferent optical configurations (e.g., each providing a differentconfiguration of image sensor 208 and/or lens 210) supported by thecamera.

Just as with the camera of device 200, and for similar reasons that willbe made apparent, a dynamic range of device 200 may also be highlyinfluenced or determined by various characteristics associated with afield of view of a projector included within device 200. For example,characteristics such as a resolution of projector component 216, amagnification power of lens 218, and/or other optical or electricalcharacteristics of the projector may serve as determining factors forthe dynamic range of device 200.

As a result, it may be desirable to employ different projectorcomponents 216 and/or different lenses 218 to implement differentcharacteristics (e.g., different resolutions, different magnificationpowers, different projection technologies, etc.) at different times. Forexample, when device 200 is detected to be relatively close to aphysical surface onto which augmented reality content is to be projectedin the real-world environment (e.g., such that the augmented realitycontent to be projected fills up a relatively large amount of theavailable resolution of projector component 216), it may be moredesirable to use a different lens 218 and/or one or more differentprojector components 216 than when device 200 is detected to berelatively remote to the physical surface (e.g., such that the augmentedreality content fills up a relatively small amount of the availableresolution of the projector component 216). To this end, as certainimplementations of image projection control module 214 direct projectorcomponent 216 to project projection 220, the content projection mayinclude selecting a projection parameter associated with a field of viewof the projector. For example, as with the capture parameter describedabove, the projection parameter may designate a particular lens from aplurality of different lenses included within the projector.

Additionally, or as an alternative to including projector componentsand/or different lenses, the configuration of projector component 216with respect to lens 218 (e.g., or an adjustable set of lensescollectively implementing lens 218) may also be altered to achieve someof the differences in characteristics described above. For example, theprojector may achieve different characteristics by mechanically and/orelectrically reconfiguring (e.g., sliding, moving, etc.) projectorcomponent 216, lens 218, or components associated therewith such asthose described above for lens 210. As such, another exemplary projectorparameter that may be selected by device 200 (e.g., by image projectioncontrol module 214) may designate a particular optical configurationfrom a plurality of different optical configurations (e.g., eachproviding a different configuration of projector component 216 and/orlens 218) supported by the projector.

In addition to the components of device 200 associated with the cameraand the projector, device 200 may further include additional componentssuch as one or more spatial sensors 222, one or more componentsimplementing power and other circuitry 224, and/or any other circuitryor mechanical or electrical components as may serve a particularimplementation.

Spatial sensors 222 may include various sensors configured to facilitatedevice 200 in determining where and how device 200 is located andoriented in space. For example, spatial sensors 222 may include gyrosensors, GPS and other locational sensors, accelerometers and othermotion sensors, compasses and other magnetic sensors, and/or any othersuitable spatial sensors for determining a spatial orientation of device200, for determining a spatial location (e.g., an absolute or relativelocation) of device 200, for detecting movement of device 200 in space,or the like. In some examples, spatial sensors 222 may include awireless radio component (e.g., for communication with a WiFi network, acellular network, etc.) that is configured to determine location byproximity to a particular network or network hub (e.g., as determined bya network name, a signal strength, etc.). As will be described below,spatial sensors 222 may be useful for determining when a virtual targetobject (e.g., a target object that is not visible in a video feed) isincluded within a field of view of the camera.

Power and other circuitry 224 may include a battery or other powersupply and associated circuitry configured to deliver power to thecamera and projector components of device 200 described above. Power andother circuitry 224 may further include any other mechanical orelectrical components as may serve a particular implementation. Forinstance, additional computing components (e.g., processor components,memory components, storage components, etc.) may be implemented withinpower and other circuitry 224 as may be appropriate. As another example,power and other circuitry 224 may include lighting equipment such as acamera flash lamp, an infrared lamp and/or sensor for implementing nightvision projections of augmented reality content into the real-worldenvironment, or the like.

In operation, augmented reality presentation systems and augmentedreality projection devices such as system 100, device 110, and/or device200 may project augmented reality content into a real-world environmentby performing any of various operations as may serve a particularimplementation. For example, certain operations may be performed duringan initialization process (e.g., a calibration process or the like)and/or at periodic times during the lifetime of the augmented realityprojection device (e.g., in response to a button press or other optionselected in any suitable way). These operations may be referred toherein as special operations. Once the special operations have beenperformed, other operations may be performed during normal use of theaugmented reality projection device. These operations may be referred toherein as normal operations.

To illustrate various special and normal operations, FIG. 3 showsexemplary operations 300 (e.g., operations 300-1 and 300-2) that may beperformed by an augmented reality presentation system such as system 100or the augmented reality presentation system integrated into device 200to project augmented reality content into a real-world environment.Specifically, FIG. 3 illustrates a plurality of special operations 300-1including a target object training operation 302, a camera calibrationobject 304, and a device calibration operation 306, as well as aplurality of normal operations 300-2 including an image captureoperation 308, a target object recognition operation 310, a contentidentification operation 312, a content projection operation 314, and aprojection stabilization operation 316. Each of operations 300 will nowbe described in more detail with reference to various aspects of FIGS.4A through 9B below.

As mentioned above, special operations 300-1 may each be performedbefore an augmented reality projection device will be able to properlyperform normal operations 300-2. For example, target object trainingoperation 302 may be performed by an augmented reality presentationsystem prior to projecting augmented reality content into a real-worldenvironment in order to designate one or more objects within thereal-world environment to act as target objects that are to beidentified and augmented. Specifically, target object training operation302 may include analyzing, storing, predetermining, designating, and/orotherwise setting up physical and/or virtual target objects includedwithin the real-world environment for the augmented reality projectiondevice to later identify and augment (e.g., by projecting augmentedreality content onto or near to the target objects).

Target objects designated by target object training operation 302 may beany suitable type of physical or virtual object included within areal-world environment. Physical target objects may include visiblereal-world objects that may be captured (e.g., represented within avideo feed captured by a camera), analyzed, and recognized by anaugmented reality presentation system using image recognition techniquesor the like. For example, physical target objects may bethree-dimensional real-world objects such as tables, chairs, people,particular products (e.g., certain makes of vehicles, particular modelsof appliances, etc.), certain portions or features of such real-worldobjects, or the like. In some examples, rather than three-dimensionalobjects or portions of such objects, physical target objects may betwo-dimensional images found in the real-world environment. For example,physical target objects may include symbolic images such as brand logos,generic or specific augmented reality markers (e.g., QR codes, barcodes,etc.), unique images such as paintings or other artwork, and so forth.

In some examples, virtual target objects may be used in addition or asan alternative to physical target objects. Virtual target objects mayrefer to “markerless” target objects within the real-world environmentor, in other words, target objects that are not directly associated withparticular real-world objects but rather are associated with otheraspects of the real-world environment such as a particular location(e.g., a tagged or designated location not specifically associated withany recognizable physical real-world object) within the real-worldenvironment. As such, virtual target objects may not be visible in thesame way as physical target objects are (e.g., able to be captured by acamera and represented within a video feed), but virtual target objectsmay still be designated and identified in ways that will be describedbelow.

FIG. 4A illustrates an exemplary physical target object physicallylocated within an exemplary real-world environment. Specifically, areal-world environment 400 shown in FIG. 4A is depicted as an exhibit inan art museum, and an abstract painting 402 within the exhibit isdepicted as an exemplary physical target object that is to be designated(e.g., by way of target object training operation 302) for lateridentification and recognition by an augmented reality presentationsystem. Target object training operation 302 may be performed todesignate painting 402 to be a target object by, for example,identifying and analyzing various features of painting 402, and storingan identified feature set associated with painting 402 in a targetobject profile within a library of predetermined target object profiles.

The target object profile for painting 402 may be generated in anysuitable manner under the direction of any suitable person or process,and may be stored and maintained (e.g., within the library ofpredetermined target object profiles) within any suitable storagefacility as may serve a particular implementation. For example, aconventional feature analysis algorithm such as a Binary RobustInvariant Scalable Keypoints (“BRISK”) algorithm may be employed toidentify prominent features (e.g., corners, lines, etc.) of painting 402and to represent the identified prominent features in a feature set of atarget object profile that may be used to recognize and identifypainting 402 later when painting 402 is included within a field of viewof a camera of an augmented reality projection device. In otherexamples, the designated target object associated with painting 402 maybe a special augmented reality marker (e.g., a QR code, a barcode, orthe like) placed near painting 402, rather than painting 402 itself.

In some examples, target object training operation 302 may be performedusing the same augmented reality projection device that will later beused to identify and augment the target object, while in other examplesobject training operation 302 may be performed using a completelyseparate augmented reality projection device. In this training mode, auser directing the augmented reality projection device to perform targetobject training operation 302 may point the device to an object the userdesires to train into the system. The device may project a known patternonto the object such that the camera may detect and track the knownpattern in accordance with distortions to the known pattern that areimposed by the shape, orientation, position, etc., of the object. Thus,based on calibration operations performed previously and based on thistracked data of the known pattern projected onto the object, theaugmented reality projection device may compute the orientation andposition of the camera with respect to the surface of the object. Theaugmented reality projection device may use an algorithm to warp theimage into a frontal planar view, and to auto crop blank regions aroundthe object to automatically define a target object profile. Additionallyor alternatively, defining the target object profile may involvepresenting the user an opportunity to manually perform, correct, and/orrefine the cropping to define the desired target area of the objectusing a touch screen interface or the like on the device. In still otherexamples, object training operation 302 may be performed virtually(e.g., using an image from an image database) rather than by using anaugmented reality projection device.

Once target object training operation 302 has been performed to generatea target object profile associated with the target object of painting402, the target object profile may be stored (e.g., with other suchtarget object profiles) in a library of predetermined target objectprofiles to be accessed by augmented reality presentation systemsassociated with users who will later be located in real-worldenvironment 400 and may wish to experience augmented reality contentassociated with painting 402. Such a library may be stored in anysuitable storage facility that the augmented reality presentationsystems may access. For example, the library may be stored on a storagefacility of an augmented reality projection device integrated with anaugmented reality presentation system such as device 200. When a user ofdevice 200 enters the museum, for instance, he or she may be able todownload, onto device 200, museum-specific content (e.g., including thelibrary of predetermined target object profiles) as a paid orcomplimentary service associated with entry to the museum. In otherexamples, the library may be stored on a storage facility associatedwith the museum, such as on a server that provides access to the libraryto augmented reality projection devices within the museum over awireless local area network or the like. In still other examples, thelibrary may be stored externally to the museum (e.g., on a cloud serverthat may or may not be associated with the museum or a service provider)and accessed by way of one or more wireless networks, mobile carriernetworks, the Internet, and/or any other suitable networks employing anycommunication technology as may serve a particular implementation.

While the example described in relation to FIG. 4A is specific to amuseum with artwork such as painting 402, it will be understood that theprinciples described in relation to the museum are intended to beexemplary only. As such, the same principles described above may applyin any of various different real-world environments associated withvarious different venues, locations, and scenarios. For instance,applications of the invention may be employed in a factory (e.g., toprovide repair or usage instructions for particular equipment), anentertainment venue (e.g., an amusement park ride, a haunted house,etc.), a home, or in any other environment as may serve a particularimplementation.

In certain examples, target objects may not be physical real-worldobjects (e.g., such as painting 402), but, rather, may be virtualobjects within the real-world environment. For example, as describedabove, virtual target objects may not be visible within the real-worldenvironment and/or may not correspond to specific real-world objects,but, rather, may be associated with particular locations or otheraspects of the real-world environment.

As one example, virtual target object training 302 may be performed forvirtual target objects by different users of respective augmentedreality projection devices who are playing a virtual hide and seek game.For instance, one user may “hide” a virtual target object (e.g., forother users to later “seek” or search for) at a particular locationwithin a real-world environment by designating the particular locationas a site of the virtual target object using a button press or otherselection mechanism provided by the augmented reality projection device.

As another example, a user may designate a markerless surface (e.g., ananchoring point at a particular portion of a white, featureless wall) asa makeshift screen for displaying augmented reality content projectedonto the screen. This may allow a user to take advantage ofstabilization features of augmented reality presentation systems and/oraugmented reality projection devices described herein to project andview content (e.g., watch a video, read text, etc.) at a particularlocation. For instance, one or more people may enjoy an impromptucontent presentation using an augmented reality projection device thatautomatically stabilizes the projection so that the image contentremains steady and easy to view even though the projector may behandheld by a user rather than statically mounted on a tripod or othersuch stabilizing mechanism.

FIG. 4B illustrates exemplary virtual target objects virtually locatedwithin an exemplary real-world environment. Specifically, a real-worldenvironment 404 is depicted as an interior of a home including, forexample, a stairway leading to an overlook area of a second level, adining area having a table and other objects, and so forth. In FIG. 4B,a first virtual target object 406 is illustrated to be disposed on theoverlook at the top of the stairway while a second virtual target object408 is illustrated on the tabletop of the dining room table. Asdescribed above, these virtual target objects may be designatedpreviously by one user for discovery by another (e.g., in a hide andseek game or the like), may be designated by a particular user for hisor her own immediate use (e.g., as a makeshift screen or the like), ormay be designated by any other person for any other use as may serve aparticular implementation.

In some examples, target object training operation 302 may be performed,for virtual target objects such as target objects 406 and 408, in asimilar way as for physical target object such as painting 402,described above. Specifically, for example, one or more prominentfeatures of the overlook area and/or the dining room table may beanalyzed and stored in respective target object profiles associated withtarget objects 406 and 408. However, because virtual target objects maynot be directly associated with readily recognizable real-world objects(e.g., paintings, augmented reality markers, etc.), it may be difficultin certain situations to detect a sufficiently unique feature set forreal-world objects near where virtual target objects are placed. Forexample, the wall area upon which target object 406 is located and/orthe tabletop area upon which target object 408 is located may berelatively featureless, making it difficult for augmented realitypresentation systems to later recognize these areas based solely oncaptured visual information.

Accordingly, target object training operation 302 may further includedetecting, analyzing, and storing various aspects of a location and/oran orientation that an augmented reality projection device may have whenthe virtual target objects are within the field of view. For example,such aspects may be detected based on information detected by spatialsensors of the augmented reality projection device such as spatialsensors 222 of device 200. Data representative of the location andorientation information detected by the spatial sensors may be includedwithin a target object profile for a particular target object along withinformation representative of a visual feature set for the target objectand/or any other information as may serve a particular implementation.

Returning to FIG. 3, special operations 300-1 include two types ofcalibration that may be performed prior to normal operation of anaugmented reality presentation system along with the target objecttraining operation 302 that has been described.

First, camera calibration operation 304 may be performed with respect toa camera of a particular augmented reality projection device prior tothe device being used. Camera calibration operation 304 may be performedby determining intrinsic parameters of the camera such as a focallength, an image sensor format, a principal point (e.g., an image centerpoint), a lens distortion, and/or any other suitable intrinsicparameters associated with the camera. Such calibration may be done inany suitable way such as by capturing and analyzing a known andreadily-recognizable pattern (e.g., a checkboard pattern or the like).

Second, device calibration operation 306 may be performed with respectto both the camera and the projector within a particular augmentedreality projection device. Specifically, device calibration operation306 may be performed to determine a rotation and translation (e.g., aheading and position) of a camera and a projector statically mountedalongside one another within the augmented reality projection device.For example, the rotation and translation may be determined for thecamera and projector in relation to one another in relation to a localcoordinate system associated with the augmented reality projectiondevice or in relation to a world coordinate system. Device calibrationoperation 306 may be performed to facilitate dynamic stabilization ofprojections, as will be made apparent below. However, it will beunderstood that device calibration operation 306 may be optional (e.g.,may be omitted) for implementations of the systems and methods forprojecting augmented reality content into a real-world environment thatdo not involve dynamically stabilizing the projections.

For purposes of stabilizing a projection on a particular portion of aphysical surface within a real-world environment, the relationshipbetween an image sensor component within an augmented reality projectiondevice (e.g., image sensor 208 of device 200) and a projector componentwithin the augmented reality projection device (e.g., projectorcomponent 216 of device 200) may be mathematically described by Equation1, below.[R|T]_(Target)=[R|T]_(sensor)*[R|T]_(Augmented) ⁽⁻¹⁾  (Equation 1)

In Equation 1, each variable “[R|T]” refers to a matrix representationof particular rotation and translation parameters describing theposition and orientation of a particular component. Specifically,[R|T]_(Target) represents a matrix describing a position and orientationof a specific portion of a physical surface within a real-worldenvironment upon which the projection is projected in relation to theimage sensor of the camera. [R|T]_(Sensor) represents a matrixdescribing a relative position and orientation difference between theimage sensor of the camera and the projector component. [R|T]⁽⁻¹⁾_(Augmented) represents an inverse matrix of a matrix describing aposition and orientation of a model of augmented reality content to beprojected with respect to the projector component. The “*” operator inEquation 1 represents a matrix multiplication.

Accordingly, to perform device calibration operation 306, an augmentedreality presentation system must solve for [R|T]_(Sensor) for a known(e.g., controlled) target matrix [R|T]_(Target) and inverse augmentedmatrix [R|T]⁽⁻¹⁾ _(Augmented). The target matrix and augmented matrixmay be setup and controlled in any suitable way during devicecalibration operation 306 to allow the sensor matrix [R|T]_(Sensor) tobe determined. Thereafter, as will be described below, this calibratedvalue for [R|T]_(Sensor) will be used in Equation 1 to dynamicallydetermine, in real time during normal operation, the augmentation matrix(e.g., to determine how augmented reality content is to be rotated andtransformed so as to maintain a stabilized appearance with respect tothe portion of the physical surface onto which it is projected).

Normal operations 300-2 may be performed consecutively or concurrentlywith one another (e.g., in real time) once special operations 300-1 havebeen successfully performed to calibrate the camera, to (optionally)calibrate the augmented reality projection device, and to train (e.g.,designate) at least one target object. However, while special operations300-1 may, in some examples, be treated as one-time, initialization-typeoperations, it will be understood that, in other examples, specialoperations 300-1 may be repeated periodically (e.g., before or aftereach normal operation session, while normal operations 300-2 areongoing, etc.). For example, as described above, target object trainingoperation 302 may be performed under the direction of users to train newtarget objects in various scenarios described above. Or, as anotherexample, if the augmented reality projection device is altered in someway (e.g., dropped or damaged, repaired to receive new components,etc.), camera calibration operation 304 and/or device calibrationoperation 306 may be performed again. Each of normal operations 300-2will now be described.

Image capture operation 308 may include capturing a portion of areal-world environment that is included within a field of view of acamera within an augmented reality projection device, as describedabove. Thus, for example, image capture operation 308 may generate avideo feed of images that the camera captures from the real-worldenvironment.

To illustrate, FIG. 5 depicts an exemplary image capture operation 308being performed by device 200 within real-world environment 400 (i.e.,the real-world environment including the museum exhibit featuringpainting 402 described above). As shown, device 200 may be operated by(e.g., performing operations under the direction of) a user 502 whoholds device 200 is his or her hand in a manner analogous to holding aflashlight. FIG. 5 shows that, while user 502 points device 200 at aphysical surface (e.g., a wall) upon which painting 402 is displayed, afield of view 504 of the camera within device 200 extends over most ofthe wall, including encompassing the entirety of painting 402. However,it will be understood that user 502 may be free to move and rotatedevice 200 so that, at other times, field of view 504 may extend overother areas not including the entirety of painting 402. For example,user 502 may point device 200 left, right, up, down, and/or may carrydevice 200 closer to or farther from painting 402 at will. Additionally,as described above, it will be understood that field of view 504 may bedetermined in part by sensor parameters (e.g., particular lenses, imagesensors, optical configurations, etc.) that may be selected for thecamera of device 200 at any particular time.

The next normal operation 300-2 shown in FIG. 3 is target objectrecognition operation 310. In target object recognition operation 310,an augmented reality presentation system may determine that a targetobject located within a real-world environment is included within thefield of view of the camera. For example, referring to the exampleillustrated in FIG. 5, device 200 may determine that the target objectof painting 402 is included within (e.g., fully or partially includedwithin) field of view 504. This determination may be performed byapplying object recognition techniques to images of real-world objectscaptured in the video feed, by determining a location and/or orientationof device 200 with respect to a virtual target object using spatialsensors 222, and/or in any other suitable way.

For example, FIG. 6 illustrates an exemplary target object recognitionoperation 310 being performed by device 200 based on a video feedcaptured by the camera of device 200 and depicting portions ofreal-world environment 400 within field of view 504. Specifically, asshown, a target object recognition 600 may be performed by target objectrecognition operation 310 by comparing data from a target object profile602 with data detected within a video feed 604 captured by the camera.By recognizing painting 402 within video feed 604 in this way, device200 may determine that the target object of painting 402 is includedwithin field of view 504 of the camera.

For a target object such as painting 402 that is a physical targetobject physically located within real-world environment 400, system 200may determine that the target object is included within field of view504 by identifying (e.g., within video feed 604) a feature set 606 ofthe physical target object and determining that the identified featureset 606 matches a feature set 608 of target object profile 602 (e.g., atarget object profile from a library of predetermined target objectprofiles). A feature set such as feature set 606 and/or 608 may bedetermined and matched in any suitable way. For example, variousprominent features (e.g., corners, etc.) represented by Xs in FIG. 6 maybe selected for feature sets 606 and 608 because these features may bereadily detectable by image processing algorithms regardless of whetherthe image is viewed straight on (e.g., such as is the case for targetobject profile 602), at an angle (e.g., such as is the case for therepresentation of painting 402 in video feed 604), at relatively closeproximity, at a relatively far distance, or the like. Additionallyfeature sets such as feature sets 606 and 608 may be matched when one isa mirror image to the other, when one is upside down in relation to theother, or when the features sets are otherwise detected in differentorientations and/or dispositions.

Feature matching illustrated in FIG. 6 may provide point-to-pointcorrespondences between the target object and a reference imagerepresented in the target object profile. However, once target objectrecognition 600 has successfully been performed, it may becomputationally expensive to continuously perform feature matching inthis way from frame to frame of video feed 604. Accordingly, in certainexamples, a few features from feature sets 606 and 608 may each betracked from frame to frame such that reasonable assumptions aboutlocations of other features may be made without repeatedly performingfeature matching operations for each individual frame.

As mentioned above, in examples involving virtual target objects, targetobject recognition operation 310 may be performed in a different way.For example, for a target object that is a virtual target objectvirtually located within a real-world environment (e.g., such as one oftarget objects 406 or 408 described above), feature matching may also beused in a similar way (e.g., to recognize the overlook wall above thestairway in the case of target object 406, to recognize the surface ofthe tabletop in the case of target object 408, etc.). Additionally, asmentioned above in the context of training these target objects togenerate respective target object profiles, spatial sensors (e.g.,spatial sensors 222 of device 200) may facilitate determining thatvirtual target objects are included within a field of view of a camera.Specifically, device 200 may determine that such a target object isincluded within the field of view of the camera by determining (e.g.,based on sensor output from one or more sensors included within device200 such as spatial sensors 222) a location and orientation of device200 with respect to a global coordinate system associated withreal-world environment 400. Device 200 may then determine (e.g., basedon the determined location and orientation and based on a target objectprofile associated with the virtual target object in a library ofpredetermined target object profiles) that the virtual target object isincluded within the field of view of the camera.

Once a video feed has been captured (e.g., by way of image captureoperation 308) and a target object has been determined to be includedwithin the field of view of the camera (e.g., by way of target objectrecognition operation 310) as described above, content identificationoperation 312 may be performed. For example, content identificationoperation 312 may involve identifying (e.g., determining, accessing froma storage facility, searching for, downloading, etc.) augmented realitycontent associated with the target object determined to be includedwithin the field of view.

The augmented reality content identified within content identificationoperation 312 may be any type of content as may serve a particularimplementation. For instance, the augmented reality content may includelight projections (e.g., a presence or an absence of light, differentcolors of light, etc.), still images, textual content, video (e.g., withor without associated audio), and/or any other type of content that maybe presented by way of a projector and as may serve a particularimplementation. In some examples, augmented reality content may beassociated with the identified target object (e.g., provided so as toaugment the target object). For example, in the example illustratedabove where the target object is painting 402 within an art museum,augmented reality content identified to be associated with painting 402may include additional information (e.g., textual information,audio/video information, etc.) about painting 402, the artist whopainted it, the period of art in which it was created, or the like. Forinstance, the augmented reality content associated with painting 402 mayinclude a short video introduction in which an art expert describespainting 402.

In other examples, a target object may be a different type of real-worldobject such as an appliance, and the augmented reality content mayinclude repair instructions or troubleshooting information (e.g., text,videos, etc.), a user's manual, or other content specifically related tothe particular appliance and/or problems the appliance may beexhibiting. In still other examples, a target object may be a virtualtarget object (e.g., a virtual target object hidden by a user in a hideand seek game) and the augmented reality content may be a message orimage created by the user that placed the virtual target object. Variousother examples of augmented reality content for various otherapplications of augmented reality projection devices may be employed asmay serve a particular implementation.

Augmented reality content may be identified in any suitable way. Forexample, an augmented reality presentation system may access data storedwithin a target object profile of an identified target object, follow alink or other instructions included in the target object profile toaccess the augmented reality content, and/or determine, find, and accessthe augmented reality content in any other suitable way.

To illustrate, FIG. 7 shows an exemplary library 700 of predefinedtarget object profiles 702 (e.g., target object profiles 702-1 through702-N). As explicitly shown in target object profile 702-1 (and as willbe understood to similarly be present in each of the additional targetobject profiles 702-2 through 702-N), each target object profile 702 mayinclude target object data (e.g., such as target object data 704 intarget object profile 702-1) and augmented reality content (e.g., suchas augmented reality content 706 in target object profile 702-1).

Target object profile data 704 may include information used to determinethat a target object is included within the field of view of the camera.For example, data illustrated in target object profile 602 in FIG. 6(e.g., including data representative of feature set 608, etc.) may beincluded within target object profile data 704, as well as dataassociated with a spatial location of a virtual target object tofacilitate determining that a virtual target object is included withinthe field of view.

Augmented reality content 706 may include data representative ofaugmented reality content (e.g., data accessible directly from library700) or a link or instructions whereby an augmented reality presentationsystem may access data representative of the augmented reality content.For example, rather than having video data directly stored in library700 (e.g., which may be stored within a storage facility of anintegrated augmented reality projection device such as device 200),augmented reality content 706 may be implemented by a link to video datastored elsewhere (e.g., on a local server, on a remote cloud server,etc.). As another example, augmented reality content 706 may beimplemented by instructions indicating that augmented reality content isto be accessed by performing an Internet search or the like (e.g., toaccess information provided by an online encyclopedia or search engine,etc.).

While only target object data 704 and augmented reality content 706 areillustrated in target object profile 702-1 in FIG. 7, it will beunderstood that any other suitable information may also be includedwithin each target object profile 702 and/or within library 700generally. For instance, in some examples, data representative of aparticular physical surface upon which augmented reality content is tobe projected may be included within library 700. For example, athree-dimensional model of the surface, data representative of thecurvature of the surface, a color of the surface, or other suitablecharacteristics may be stored to allow augmented reality content to beprojected onto a curved surface with minimal or no distortion, to beprojected without color being washed out, or the like.

Referring again to normal operations 300-2 in FIG. 3, an augmentedreality presentation system may perform content project operation 314subsequent to or concurrently with operations 308 through 312, describedabove. More specifically, once augmented reality content associated witha target object in the field of view of the augmented reality projectiondevice has been identified and accessed, the augmented realitypresentation system may direct a projector to project the content onto aphysical surface within the real-world environment.

To illustrate, FIG. 8 shows an exemplary content projection operation314 being performed by device 200. As introduced in previous figuresillustrated above, user 502 may operate device 200 by pointing device200 in the direction of painting 402 within the museum exhibit ofreal-world environment 400. As such, field of view 504 of the camera ofdevice 200 may extend over the entirety of painting 402 and over a largeportion of the wall upon which painting 402 is displayed. FIG. 8 furtherillustrates that the projector of device 200 projects augmented realitycontent 802 onto a physical surface 804 included within real-worldenvironment 400 (i.e., the wall upon which painting 402 is presented).As shown, augmented reality content is included within a field of view806 of the projector that is similar to (but distinct from) field ofview 504 of the camera.

As shown, while field of view 806 fully extends over painting 402 andmuch of physical surface 804, augmented reality content 802 is projectedwithin a relatively small portion of field of view 806 so as to bepresented at a particular portion 808 of physical surface 804 that isnext to painting 402. For example, portion 808 may be defined within thetarget object profile for painting 402 and may be designated to beadjacent to (e.g., near but not directly overlapping with) painting 402,to be of an appropriate size (e.g., a size that is large enough to beeasy for user 502 to see while not being so large as to overpowerpainting 402), and/or to have other desirable characteristics.

In certain implementations, as the projector of device 200 projectsaugmented reality content 802 onto physical surface 804, augmentedreality content 802 may be viewable by a plurality of people inreal-world environment 400. For example, even though user 502 is theonly person shown to have an augmented reality projection device (i.e.,device 200) for projecting augmented reality content into real-worldenvironment 400, augmented reality content 802 may be viewable not onlyby user 502, but also by another person 810 and/or by any other peoplein real-world environment 400. This may be advantageous compared to aconventional augmented reality player device which, if operated by user502, would only allow user 502 to view augmented reality content 802(e.g., by way of a display screen worn by user 502 or the like). Incontrast with such conventional systems, device 200 may presentaugmented reality content 802 only on physical surface 804 (e.g., atportion 808 of physical surface 804) and may abstain from directingaugmented reality content 802 to be displayed on a screen visible toonly one person (e.g., a screen connected to device 200, a screenvisible only to user 502, etc.).

As shown, field of view 504 of the camera included within device 200 andfield of view 806 of the projector included within device 200 maysubstantially overlap due to the fact that the camera and the projectormay be mounted (e.g., statically mounted) alongside one another withinthe enclosure of device 200, as described above. As a result, as theprojector projects augmented reality content 802 onto physical surface804, the target object of painting 402 may be included, together withportion 808 of physical surface 804 onto which augmented reality content802 is projected, within field of view 504 of the camera, as shown.

In certain implementations, the projection of augmented reality content802 onto physical surface may not be dynamically stabilized. In otherwords, once device 200 identifies the target object and beginsprojecting augmented reality content 802, the projection may move aroundphysical surface 804 and/or other physical surfaces within real-worldenvironment 400 in accordance with where user 502 points device 200(e.g., including getting bigger as the projector moves away from aphysical surface and getting smaller as the projector gets closer). Insuch implementations, projection stabilization operation 316 (i.e., thefinal normal operation 300-2 illustrated in FIG. 3) may be omitted.

In other implementations, however, projection stabilization operation316 may be performed to dynamically stabilize the projection ofaugmented reality content 802 to remain, with the same relative size andorientation, at portion 808 of physical surface 804. For example, bydynamically and continuously performing projection stabilizationoperation 316, augmented reality content 802 may be stabilized atportion 808 even as user 502 moves and points device 200 in differentways (e.g., as long as portion 808 is included within field of view 806of the projector). More particularly, as part of directing the projectorto project augmented reality content 802 onto physical surface 804,device 200 may direct the projector to dynamically stabilize aprojection of augmented reality content 802 at the particular portion808 of physical surface 804 in response to a change to at least one of aposition and an orientation of device 200 with respect to portion 808 ofphysical surface 804.

As such, having the target object of painting 402 included within fieldof view 502 as augmented reality content 802 is projected (as describedabove) may facilitate the dynamic stabilization. For example, this mayallow device 200 to keep apprised (e.g., via the video feed in whichportions of real-world environment 400 within field of view 504 arecaptured) of the spatial relationship of device 200 and painting 402(i.e., the target object adjacent to portion 808 where augmented realitycontent 802 is to be projected).

FIGS. 9A and 9B illustrate different exemplary projection stabilizationoperations 316 being performed by device 200. Specifically, in a firstprojection stabilization operation 316 illustrated by FIG. 9A, the fieldof view of the projector of device 200 (e.g., field of view 806 in FIG.8) is shown to move from a first position 902-1 to a second position902-2 by way of a change 904 to an orientation of device 200. Forexample, while painting 402 remains statically placed on the wall, user502 may reorient device 200 from pointing at position 902-1 to pointingat position 902-2. In spite of this movement, however, it may bedesirable for augmented reality content 802 to remain stabilized atportion 808 adjacent to painting 402. Accordingly, in response to change904, a projection stabilization operation 316 may be performed toreposition the projection of augmented reality content 802 from themiddle-top region of the field of view when it is at position 902-1 tobeing closer to the bottom left corner of the field of view when it isat position 902-2, as shown.

Similarly, in a second projection stabilization operation 316illustrated by FIG. 9B, the field of view of the projector is shown togrow from a first size 906-1 to a second size 906-2 by way of a change908 to a position of device 200. For example, while painting 402 remainsstatically placed on the wall, user 502 may carry device 200 from aposition relatively close to painting 402 (e.g., where painting 402 andportion 808 take most of the projector's resolution because the field ofview has relatively small size 906-1) to a position further away frompainting 402 (e.g., where painting 402 and portion 808 take less of theprojector's resolution because the field of view has relatively largesize 906-2). As in FIG. 9A, however, it may be desirable for augmentedreality content 802 to remain stabilized (e.g., remain at a constantsize) at portion 808 adjacent to painting 402 in spite of this change tothe position of device 200. Accordingly, in response to change 908, aprojection stabilization operation 316 may be performed to resize theprojection of augmented reality content 802 from being relatively large(e.g., with respect to size 906-1 of the field of view of the projector)prior to change 908 to being relatively small (e.g., with respect tosize 906-2 of the field of view of the projector) after change 908, asshown.

Either or both of the projection stabilization operations 316illustrated in FIGS. 9A and 9B may be repeatedly performed to maintainstabilization as user 502 moves and reorients device 200 with respect toportion 808 in real-world environment 400. These projectionstabilization operations 316 may be performed in any manner as may servea particular implementation. For example, device 200 may direct theprojector to dynamically stabilize the projection of augmented realitycontent 802 by 1) tracking (e.g., based on the video feed and inresponse to change 904, change 908, or the like) portion 808 of physicalsurface 804, 2) determining (e.g., based on the tracking) a changedposition and/or a changed orientation of device 200 with respect toportion 808 of physical surface 804, 3) adjusting (e.g., based on thedetermining of the changed position and/or the changed orientation)augmented reality content 802 (e.g., such as by moving it to a differentpart of the field of view, increasing or decreasing its size within thefield of view, etc.), and 4) directing the projector to project theadjusted augmented reality content onto portion 808 of physical surface804.

One or more of these steps (i.e., tracking, determining, adjusting, anddirecting), as well as additional steps as may serve a particularimplementation, may be performed concurrently or in any suitable orderto perform stabilization operation 316. Each step may be performed inany suitable way. For example, the step of determining the changedposition and/or the changed orientation of device 200 with respect toportion 808 may be performed by solving Equation 2 below, which definesthe relationship of a pose (e.g., a position and an orientation) of thecamera of device 200 with respect to portion 808.s*x=K*P*X  (Equation 2)

Specifically, in Equation 2, s represents a scale factor, x representspixel locations of identified features of the projection of augmentedreality content 802, K represents the camera calibration matrix of thecamera included within device 200 (e.g., as determined by cameracalibration operation 304), P represents the pose of the camera withrespect to portion 808 (i.e., the variable that is to be solved for),and X represents the three-dimensional locations of the identifiedfeatures in space. Because most of the variables in Equation 2 arerepresented by matrices, Equation 2 may be rewritten in Matrix form asEquation 3, below.

$\begin{matrix}{{s\begin{bmatrix}x \\y \\1\end{bmatrix}} = {{\begin{bmatrix}f_{x} & 0 & u_{0} \\0 & f_{y} & v_{0} \\0 & 0 & 1\end{bmatrix}\begin{bmatrix}r_{11} & r_{12} & r_{13} & t_{1} \\r_{21} & r_{22} & r_{23} & t_{2} \\r_{31} & r_{32} & r_{33} & t_{3}\end{bmatrix}}\begin{bmatrix}X \\Y \\Z \\1\end{bmatrix}}} & \left( {{Equation}\mspace{14mu} 3} \right)\end{matrix}$

In Equation 3, variables x and y refer to the two-dimensionalcoordinates of pixel location x in Equation 2. Variables f_(x) and f_(y)refer to a focal length and u₀ and v₀ refer to a principle point of thecamera included within the camera calibration matrix K of Equation 2.Variables r₁₁ through r₃₃ represent the 3×3 rotation matrix of thecamera in three-dimensional space (e.g., how the camera is oriented withrespect to portion 808). Variables t₁ through t₃ represent thetranslation matrix of the camera in three-dimensional space (e.g., wherethe camera is positioned with respect to portion 808). Variables X, Y,and Z refer to the three-dimensional coordinates of the featurecorresponding to the pixel location of x and y. Thus, by solving forvariables r₁₁ through r₃₃ and t₁ through t₃ in Equation 3 (i.e., solvingfor the pose matrix P in Equation 2), device 200 may determine, inresponse to a change such as change 904 or 908, how the camera withindevice 200 is posed in relation to portion 808.

Based on this calculated pose, as well as based on the spatialrelationship between the camera and the projector within device 200determined during device calibration operation 306 (described above),Equation 1 may be used to perform the step of adjusting augmentedreality content 802. For example, because Equation 1 describes themathematical relationship between image sensor 208 within device 200 andprojector component 216 within device 200, augmented reality content 802may be properly adjusted based on the rotation and translation matrixobtained by solving Equation 1 for [R|T]_(Augmented). Once adjusted inthis way, the projection of augmented reality content 802 may bestabilized at portion 808 even as changes 904, 908, and/or other suchchanges occur during operation of device 200.

FIG. 10 illustrates an exemplary method 1000 for projecting augmentedreality content into a real-world environment according to principlesdescribed herein. While FIG. 10 illustrates exemplary operationsaccording to one embodiment, other embodiments may omit, add to,reorder, and/or modify any of the operations shown in FIG. 10. One ormore of the operations shown in FIG. 10 may be performed by system 100(e.g., operating in conjunction with a separate augmented realityprojection device such as device 110), by an augmented realitypresentation system integrated with an augmented reality projectiondevice such as device 200, by any components included therein, and/or byany implementations thereof.

In operation 1002, an augmented reality presentation system may direct acamera included within an augmented reality projection device to capturea video feed of a portion of a real-world environment. For example, theportion of the real-world environment may be a portion included within afield of view of the camera. Operation 1002 may be performed in any ofthe ways described herein.

In operation 1004, the augmented reality presentation system maydetermine that a target object located within the real-world environmentis included within the field of view of the camera. For example, theaugmented reality presentation system may determine that the targetobject is included within the field of view as the camera captures thevideo feed. Operation 1004 may be performed in any of the ways describedherein.

In operation 1006, the augmented reality presentation system mayidentify augmented reality content associated with the target object.Operation 1006 may be performed in any of the ways described herein.

In operation 1008, the augmented reality presentation system may directa projector to project the augmented reality content onto a physicalsurface within the real-world environment and associated with the targetobject. For example, the projector may be included within the augmentedreality projection device and the augmented reality presentation systemmay direct the projector to project the augmented reality content ontothe physical surface as the camera captures the video feed. In someexamples, the physical surface may be physically detached from theaugmented reality projection device. Additionally, in certainimplementations, the physical surface may be included within the fieldof view of the camera while the augmented reality content is projectedonto the physical surface. Operation 1008 may be performed in any of theways described herein.

FIG. 11 illustrates an exemplary method 1100 for projecting augmentedreality content into a real-world environment according to principlesdescribed herein. While FIG. 11 illustrates exemplary operationsaccording to one embodiment, other embodiments may omit, add to,reorder, and/or modify any of the operations shown in FIG. 11. As withmethod 1000, one or more of the operations in method 1100 may beperformed by system 100, by an augmented reality presentation systemintegrated within an augmented reality projection device such as device200, by any components included therein, and/or by any implementationsthereof.

In operation 1102, a camera included within an augmented realityprojection device may capture a video feed of a portion of a real-worldenvironment. For example, the portion of the real-world environment maybe a portion included within a field of view of the camera. Operation1102 may be performed in any of the ways described herein.

In operation 1104, the augmented reality projection device may determinethat a target object located within the real-world environment isincluded within the field of view of the camera. For example, theaugmented reality projection device may determine that the target objectis included within the field of view as the camera captures the videofeed. Operation 1104 may be performed in any of the ways describedherein.

In operation 1106, the augmented reality projection device may identifyaugmented reality content associated with the target object. Operation1106 may be performed in any of the ways described herein.

In operation 1108, a projector mounted alongside the camera within theaugmented reality projection device may project the augmented realitycontent onto a physical surface within the real-world environment andassociated with the target object. In some examples, the projector mayproject the augmented reality content onto the physical surface as thecamera captures the video feed. Additionally, in certainimplementations, the physical surface may be physically detached fromthe augmented reality projection device and may be included within thefield of view of the camera while the augmented reality content isprojected onto the physical surface. Operation 1108 may be performed inany of the ways described herein.

In operation 1110, the augmented reality projection device maydynamically stabilize a projection of the projected augmented realitycontent at a particular portion of the physical surface. For example,the augmented reality projection device may dynamically stabilize theprojection in response to a change to at least one of a position and anorientation of the augmented reality projection device with respect tothe particular portion of the physical surface. Operation 1110 may beperformed in any of the ways described herein.

In certain embodiments, one or more of the systems, components, and/orprocesses described herein may be implemented and/or performed by one ormore appropriately configured computing devices. To this end, one ormore of the systems and/or components described above may include or beimplemented by any computer hardware and/or computer-implementedinstructions (e.g., software) embodied on at least one non-transitorycomputer-readable medium configured to perform one or more of theprocesses described herein. In particular, system components may beimplemented on one physical computing device or may be implemented onmore than one physical computing device. Accordingly, system componentsmay include any number of computing devices, and may employ any of anumber of computer operating systems.

In certain embodiments, one or more of the processes described hereinmay be implemented at least in part as instructions embodied in anon-transitory computer-readable medium and executable by one or morecomputing devices. In general, a processor (e.g., a microprocessor)receives instructions, from a non-transitory computer-readable medium,(e.g., a memory, etc.), and executes those instructions, therebyperforming one or more processes, including one or more of the processesdescribed herein. Such instructions may be stored and/or transmittedusing any of a variety of known computer-readable media.

A computer-readable medium (also referred to as a processor-readablemedium) includes any non-transitory medium that participates inproviding data (e.g., instructions) that may be read by a computer(e.g., by a processor of a computer). Such a medium may take many forms,including, but not limited to, non-volatile media, and/or volatilemedia. Non-volatile media may include, for example, optical or magneticdisks and other persistent memory. Volatile media may include, forexample, dynamic random access memory (“DRAM”), which typicallyconstitutes a main memory. Common forms of computer-readable mediainclude, for example, a disk, hard disk, magnetic tape, any othermagnetic medium, a compact disc read-only memory (“CD-ROM”), a digitalvideo disc (“DVD”), any other optical medium, random access memory(“RAM”), programmable read-only memory (“PROM”), electrically erasableprogrammable read-only memory (“EPROM”), FLASH-EEPROM, any other memorychip or cartridge, or any other tangible medium from which a computercan read.

FIG. 12 illustrates an exemplary computing device 1200 that may bespecifically configured to perform one or more of the processesdescribed herein. As shown in FIG. 12, computing device 1200 may includea communication interface 1202, a processor 1204, a storage device 1206,and an input/output (“I/O”) module 1208 communicatively connected via acommunication infrastructure 1210. While an exemplary computing device1200 is shown in FIG. 12, the components illustrated in FIG. 12 are notintended to be limiting. Additional or alternative components may beused in other embodiments. Components of computing device 1200 shown inFIG. 12 will now be described in additional detail.

Communication interface 1202 may be configured to communicate with oneor more computing devices. Examples of communication interface 1202include, without limitation, a wired network interface (such as anetwork interface card), a wireless network interface (such as awireless network interface card), a modem, an audio/video connection,and any other suitable interface.

Processor 1204 generally represents any type or form of processing unitcapable of processing data or interpreting, executing, and/or directingexecution of one or more of the instructions, processes, and/oroperations described herein. Processor 1204 may direct execution ofoperations in accordance with one or more applications 1212 or othercomputer-executable instructions such as may be stored in storage device1206 or another computer-readable medium.

Storage device 1206 may include one or more data storage media, devices,or configurations and may employ any type, form, and combination of datastorage media and/or device. For example, storage device 1206 mayinclude, but is not limited to, a hard drive, network drive, flashdrive, magnetic disc, optical disc, RAM, dynamic RAM, other non-volatileand/or volatile data storage units, or a combination or sub-combinationthereof. Electronic data, including data described herein, may betemporarily and/or permanently stored in storage device 1206. Forexample, data representative of one or more executable applications 1212configured to direct processor 1204 to perform any of the operationsdescribed herein may be stored within storage device 1206. In someexamples, data may be arranged in one or more databases residing withinstorage device 1206.

I/O module 1208 may include one or more I/O modules configured toreceive user input and provide user output. One or more I/O modules maybe used to receive input for a single virtual experience. I/O module1208 may include any hardware, firmware, software, or combinationthereof supportive of input and output capabilities. For example, I/Omodule 1208 may include hardware and/or software for capturing userinput, including, but not limited to, a keyboard or keypad, atouchscreen component (e.g., touchscreen display), a receiver (e.g., anRF or infrared receiver), motion sensors, and/or one or more inputbuttons.

I/O module 1208 may include one or more devices for presenting output toa user, including, but not limited to, a graphics engine, a display(e.g., a display screen), one or more output drivers (e.g., displaydrivers), one or more audio speakers, and one or more audio drivers. Incertain embodiments, I/O module 1208 is configured to provide graphicaldata to a display for presentation to a user. The graphical data may berepresentative of one or more graphical user interfaces and/or any othergraphical content as may serve a particular implementation.

In some examples, any of the facilities described herein may beimplemented by or within one or more components of computing device1200. For example, one or more applications 1212 residing within storagedevice 1206 may be configured to direct processor 1204 to perform one ormore processes or functions associated with facilities 102 through 106of system 100. Likewise, storage facility 108 of system 100 may beimplemented by or within storage device 1206.

To the extent the aforementioned embodiments collect, store, and/oremploy personal information provided by individuals, it should beunderstood that such information shall be used in accordance with allapplicable laws concerning protection of personal information.Additionally, the collection, storage, and use of such information maybe subject to consent of the individual to such activity, for example,through well known “opt-in” or “opt-out” processes as may be appropriatefor the situation and type of information. Storage and use of personalinformation may be in an appropriately secure manner reflective of thetype of information, for example, through various encryption andanonymization techniques for particularly sensitive information.

In the preceding description, various exemplary embodiments have beendescribed with reference to the accompanying drawings. It will, however,be evident that various modifications and changes may be made thereto,and additional embodiments may be implemented, without departing fromthe scope of the invention as set forth in the claims that follow. Forexample, certain features of one embodiment described herein may becombined with or substituted for features of another embodimentdescribed herein. The description and drawings are accordingly to beregarded in an illustrative rather than a restrictive sense.

What is claimed is:
 1. A method comprising: directing, by an augmentedreality presentation system, a sensor included within an augmentedreality projection device to capture an image of a portion of areal-world environment, the portion of the real-world environmentincluded within a field of view of the sensor; determining, by theaugmented reality presentation system as the sensor captures the image,that a virtual target object located within the real-world environmentis included within the field of view of the sensor, the determiningincluding determining, based on sensor output from one or more sensorsincluded within the augmented reality projection device, a location andorientation of the augmented reality projection device with respect to aglobal coordinate system associated with the real-world environment, anddetermining, based on the determined location and orientation and basedon a target object profile associated with the virtual target object ina library of predetermined target object profiles, that the virtualtarget object is included within the field of view of the sensor;identifying, by the augmented reality presentation system, augmentedreality content associated with the virtual target object; anddirecting, by the augmented reality presentation system as the sensorcaptures the image, a projector included within the augmented realityprojection device to project the augmented reality content onto aphysical surface within the real-world environment and associated withthe virtual target object, the physical surface physically detached fromthe augmented reality projection device and included within the field ofview of the sensor while the augmented reality content is projected ontothe physical surface.
 2. The method of claim 1, wherein the directing ofthe projector to project the augmented reality content onto the physicalsurface includes directing the projector to dynamically stabilize aprojection of the augmented reality content at a particular portion ofthe physical surface in response to a change to at least one of aposition and an orientation of the augmented reality projection devicewith respect to the particular portion of the physical surface.
 3. Themethod of claim 2, wherein the image is a video feed and the directingof the projector to dynamically stabilize the projection of theaugmented reality content includes: tracking, based on the video feedand in response to the change, the particular portion of the physicalsurface; determining, based on the tracking of the particular portion ofthe physical surface, at least one of a changed position and a changedorientation of the augmented reality projection device with respect tothe particular portion of the physical surface; adjusting, based on thedetermining of the at least one of the changed position and the changedorientation, the augmented reality content; and directing the projectorto project the adjusted augmented reality content onto the particularportion of the physical surface.
 4. The method of claim 1, wherein thedirecting of the sensor to capture the image includes selecting a sensorparameter associated with the field of view of the sensor, the sensorparameter designating at least one of: a particular image sensor from aplurality of different image sensors included within the sensor; aparticular lens from a plurality of different lenses included within thesensor; and a particular optical configuration from a plurality ofdifferent optical configurations supported by the sensor.
 5. The methodof claim 1, wherein the directing of the projector to project theaugmented reality content includes selecting a projection parameterassociated with a field of view of the projector, the projectionparameter designating at least one of: a particular lens from aplurality of different lenses included within the projector; and aparticular optical configuration from a plurality of different opticalconfigurations supported by the projector.
 6. The method of claim 1,further comprising: determining, by the augmented reality presentationsystem as the sensor captures the image, that a physical target objectis included within the field of view of the sensor, the physical objectphysically located within the real-world environment and visible withinthe captured image, wherein the determining that the physical targetobject is included within the field of view of the sensor includes:identifying, within the image, a feature set of the physical targetobject, and determining that the identified feature set of the physicaltarget object matches a feature set of a target object profile in alibrary of predetermined target object profiles; identifying, by theaugmented reality presentation system, additional augmented realitycontent associated with the physical target object; and directing, bythe augmented reality presentation system as the sensor captures theimage, the projector to project the additional augmented reality contentassociated with the physical target object onto an additional physicalsurface within the real-world environment and associated with thephysical target object.
 7. The method of claim 1, wherein, as theprojector projects the augmented reality content onto the physicalsurface within the real-world environment: the augmented reality contenton the physical surface is viewable by a plurality of people in thereal-world environment; and the augmented reality presentation systemabstains from further directing the augmented reality content to bedisplayed on a screen visible to only one person.
 8. The method of claim1, wherein, as the projector projects the augmented reality content ontothe physical surface, the virtual target object is included, togetherwith a portion of the physical surface onto which the augmented realitycontent is projected, within the field of view of the camera.
 9. Themethod of claim 1, further comprising including, by the augmentedreality presentation system, the target object profile within thelibrary of predetermined target object profiles based on a designation,by a first user playing a virtual hide and seek game using the augmentedreality presentation device, to hide the virtual target object in alocation that is to be discovered by a second user playing the virtualhide and seek game using the augmented reality presentation device. 10.The method of claim 1, embodied as computer-executable instructions onat least one non-transitory computer-readable medium.
 11. A methodcomprising: capturing, by a camera included within an augmented realityprojection device, a video feed of a portion of a real-worldenvironment, the portion of the real-world environment included within afield of view of the camera; determining, by the augmented realityprojection device as the camera captures the video feed, that a virtualtarget object located within the real-world environment is includedwithin the field of view of the camera, the determining includingdetermining, based on sensor output from one or more sensors includedwithin the augmented reality projection device, a location andorientation of the augmented reality projection device with respect to aglobal coordinate system associated with the real-world environment, anddetermining, based on the determined location and orientation and basedon a target object profile associated with the virtual target object ina library of predetermined target object profiles, that the virtualtarget object is included within the field of view of the sensor;identifying, by the augmented reality projection device, augmentedreality content associated with the virtual target object; projecting,by a projector mounted alongside the camera within the augmented realityprojection device and as the camera captures the video feed, theaugmented reality content onto a physical surface within the real-worldenvironment and associated with the virtual target object, the physicalsurface physically detached from the augmented reality projection deviceand included within the field of view of the camera while the augmentedreality content is projected onto the physical surface; and dynamicallystabilizing, by the augmented reality projection device, a projection ofthe projected augmented reality content at a particular portion of thephysical surface in response to a change to at least one of the positionand the orientation of the augmented reality projection device withrespect to the particular portion of the physical surface.
 12. Themethod of claim 11, embodied as computer-executable instructions on atleast one non-transitory computer-readable medium.
 13. A systemcomprising: at least one physical computing device that: directs asensor included within an augmented reality projection device to capturean image of a portion of a real-world environment, the portion of thereal-world environment included within a field of view of the sensor;determines, as the sensor captures the image, that a virtual targetobject located within the real-world environment is included within thefield of view of the sensor, the determining that the virtual targetobject is included within the field of view of the sensor includingdetermining, based on sensor output from one or more sensors includedwithin the augmented reality projection device, a location andorientation of the augmented reality projection device with respect to aglobal coordinate system associated with the real-world environment, anddetermining, based on the determined location and orientation and basedon a target object profile associated with the virtual target object ina library of predetermined target object profiles, that the virtualtarget object is included within the field of view of the sensor;identifies augmented reality content associated with the virtual targetobject; and directs, as the sensor captures the image, a projectorincluded within the augmented reality projection device to project theaugmented reality content onto a physical surface within the real-worldenvironment and associated with the virtual target object, the physicalsurface physically detached from the augmented reality projection deviceand included within the field of view of the sensor while the augmentedreality content is projected onto the physical surface.
 14. The systemof claim 13, wherein the at least one physical computing device directsthe projector to project the augmented reality content onto the physicalsurface by directing the projector to dynamically stabilize a projectionof the augmented reality content at a particular portion of the physicalsurface in response to a change to at least one of a position and anorientation of the augmented reality projection device with respect tothe particular portion of the physical surface.
 15. The system of claim14, wherein the at least one physical computing device directs theprojector to dynamically stabilize the projection of the augmentedreality content by: tracking, based on the image and in response to thechange, the particular portion of the physical surface; determining,based on the tracking of the particular portion of the physical surface,at least one of a changed position and a changed orientation of theaugmented reality projection device with respect to the particularportion of the physical surface; adjusting, based on the determining ofthe at least one of the changed position and the changed orientation,the augmented reality content; and directing the projector to projectthe adjusted augmented reality content onto the particular portion ofthe physical surface.
 16. The system of claim 13, wherein, as part ofthe directing of the sensor to capture the image, the at least onephysical computing device selects a sensor parameter associated with thefield of view of the sensor, the sensor parameter designating at leastone of: a particular image sensor from a plurality of different imagesensors included within the sensor; a particular lens from a pluralityof different lenses included within the sensor; and a particular opticalconfiguration from a plurality of different optical configurationssupported by the sensor.
 17. The system of claim 13, wherein, as part ofthe directing of the projector to project the augmented reality content,the at least one physical computing device selects a projectionparameter associated with a field of view of the projector, theprojection parameter designating at least one of: a particular lens froma plurality of different lenses included within the projector; and aparticular optical configuration from a plurality of different opticalconfigurations supported by the projector.
 18. The system of claim 13,wherein the at least one physical computing device further: determines,as the sensor captures the image, that a physical target object isincluded within the field of view of the sensor, the physical objectphysically located within the real-world environment and visible withinthe captured image, wherein the determining that the physical targetobject is included within the field of view of the sensor includes:identifying, within the image, a feature set of the physical targetobject, and determining that the identified feature set of the physicaltarget object matches a feature set of a target object profile in alibrary of predetermined target object profiles; identifies additionalaugmented reality content associated with the physical target object;and directs, as the sensor captures the image, the projector to projectthe additional augmented reality content associated with the physicaltarget object onto an additional physical surface within the real-worldenvironment and associated with the physical target object.
 19. Thesystem of claim 13, wherein, as the projector projects the augmentedreality content onto the physical surface within the real-worldenvironment: the augmented reality content on the physical surface isviewable by a plurality of people in the real-world environment; and theat least one physical computing device abstains from further directingthe augmented reality content to be displayed on a screen visible toonly one person.
 20. The method of claim 1, further comprisingincluding, by the augmented reality presentation system, the targetobject profile within the library of predetermined target objectprofiles based on a designation, by a user, of the virtual target objectfor use as a makeshift screen.